101 Things A Six Sigma Black Belt Should Know
1. In general, a Six Sigma Black Belt should be
quantitatively oriented.
2. With minimal guidance, the Six Sigma Black Belt should
be able to use data to convert broad generalizations into actionable goals.
3. The Six Sigma Black Belt should be able to make the
business case for attempting to accomplish these goals.
4. The Six Sigma Black Belt should be able to develop
detailed plans for achieving these goals.
5. The Six Sigma Black Belt should be able to measure
progress towards the goals in terms meaningful to customers and leaders.
6. The Six Sigma Black Belt should know how to establish
control systems for maintaining the gains achieved through Six Sigma.
7. The Six Sigma Black Belt should understand and be able
to communicate the rationale for continuous improvement, even after initial
goals have been accomplished.
8. The Six Sigma Black Belt should be familiar with
research that quantifies the benefits firms have obtained from Six Sigma.
9. The Six Sigma Black Belt should know or be able to
find the PPM rates associated with different sigma levels (e.g., Six Sigma =
3.4 PPM)
10. The Six Sigma Black Belt should know the approximate
relative cost of poor quality associated with various sigma levels (e.g., three
sigma firms report 25% COPQ).
11. The Six Sigma Black Belt should understand the roles
of the various people involved in change (senior leader, champion, mentor,
change agent, technical leader, team leader, facilitator).
12. The Six Sigma Black Belt should be able to design,
test, and analyze customer surveys.
13. The Six Sigma Black Belt should know how to
quantitatively analyze data from employee and customer surveys. This includes
evaluating survey reliability and validity as well as the differences between surveys.
14. Given two or more sets of survey data, the Six Sigma
Black Belt should be able to determine if there are statistically significant
differences between them.
15. The Six Sigma Black Belt should be able to quantify
the value of customer retention.
16. Given a partly completed QFD matrix, the Six Sigma
Black Belt should be able to complete it.
17. The Six Sigma Black Belt should be able to compute
the value of money held or invested over time, including present value and
future value of a fixed sum.
18. The Six Sigma Black Belt should be able to compute PV
and FV values for various compounding periods.
19. The Six Sigma Black Belt should be able to compute
the break even point for a project.
20. The Six Sigma Black Belt should be able to compute
the net present value of cash flow streams, and to use the results to choose
among competing projects.
21. The Six Sigma Black Belt should be able to compute
the internal rate of return for cash flow streams and to use the results to
choose among competing projects.
22. The Six Sigma Black Belt should know the COPQ
rationale for Six Sigma, i.e., he should be able to explain what to do if COPQ
analysis indicates that the optimum for a given process is less than Six Sigma.
23. The Six Sigma Black Belt should know the basic COPQ
categories and be able to allocate a list of costs to the correct category.
24. Given a table of COPQ data over time, the Six Sigma
Black Belt should be able to perform a statistical analysis of the trend.
25. Given a table of COPQ data over time, the Six Sigma
Black Belt should be able to perform a statistical analysis of the distribution
of costs among the various categories.
26. Given a list of tasks for a project, their times to
complete, and their precedence relationships, the Six Sigma Black Belt should
be able to compute the time to completion for the project, the earliest
completion times, the latest completion times and the slack times. He should
also be able to identify which tasks are on the critical path.
27. Give cost and time data for project tasks, the Six
Sigma Black Belt should be able to compute the cost of normal and crash
schedules and the minimum total cost schedule.
28. The Six Sigma Black Belt should be familiar with the
basic principles of benchmarking.
29. The Six Sigma Black Belt should be familiar with the
limitations of benchmarking.
30. Given an organization chart and a listing of team
members, process owners, and sponsors, the Six Sigma Black Belt should be able
to identify projects with a low probability of success.
31. The Six Sigma Black Belt should be able to identify
measurement scales of various metrics (nominal, ordinal, etc).
32. Given a metric on a particular scale, the Six Sigma
Black Belt should be able to determine if a particular statistical method
should be used for analysis.
33. Given a properly collected set of data, the Six Sigma
Black Belt should be able to perform a complete measurement system analysis,
including the calculation of bias, repeatability, reproducibility, stability,
discrimination (resolution) and linearity.
34. Given the measurement system metrics, the Six Sigma
Black Belt should know whether or not a given measurement system should be used
on a given part or process.
35. The Six Sigma Black Belt should know the difference
between computing sigma from a data set whose production sequence is known and
from a data set whose production sequence is not known.
36. Given the results of an AIAG Gage R&R study, the
Six Sigma Black Belt should be able to answer a variety of questions about the measurement
system.
37. Given a narrative description of "as-is"
and "should-be" processes, the Six Sigma Black Belt should be able to
prepare process maps.
38. Given a table of raw data, the Six Sigma Black Belt
should be able to prepare a frequency tally sheet of the data, and to use the
tally sheet data to construct a histogram.
39. The Six Sigma Black Belt should be able to compute
the mean and standard deviation from a grouped frequency distribution.
40. Given a list of problems, the Six Sigma Black Belt
should be able to construct a Pareto Diagram of the problem frequencies.
41. Given a list which describes problems by department,
the Six Sigma Black Belt should be able to construct a Cross tabulation and use
the information to perform a Chi-square analysis.
42. Given a table of x and y data pairs, the Six Sigma
Black Belt should be able to determine if the relationship is linear or
non-linear.
43. The Six Sigma Black Belt should know how to use
non-linearity’s to make products or processes more robust.
44. The Six Sigma Black Belt should be able to construct
and interpret a run chart when given a table of data in time-ordered sequence.
This includes calculating run length, number of runs and quantitative trend evaluation.
45. When told the data are from an exponential or Erlang
distribution the Six Sigma Black Belt should know that the run chart is
preferred over the standard X control chart.
46. Given a set of raw data the Six Sigma Black Belt
should be able to identify and compute two statistical measures each for
central tendency, dispersion, and shape.
47. Given a set of raw data, the Six Sigma Black Belt
should be able to construct a histogram.
48. Given a stem & leaf plot, the Six Sigma Black
Belt should be able to reproduce a sample of numbers to the accuracy allowed by
the plot.
49. Given a box plot with numbers on the key box points,
the Six Sigma Black Belt should be able to identify the 25th and 75th
percentile and the median.
50. The Six Sigma Black Belt should know when to apply
enumerative statistical methods, and when not to.
51. The Six Sigma Black Belt should know when to apply
analytic statistical methods, and when not to.
52. The Six Sigma Black Belt should demonstrate a grasp
of basic probability concepts, such as the probability of mutually exclusive events,
of dependent and independent events, of events that can occur simultaneously,
etc.
53. The Six Sigma Black Belt should know factorials,
permutations and combinations, and how to use these in commonly used
probability distributions.
54. The Six Sigma Black Belt should be able to compute
expected values for continuous and discrete random variables.
55. The Six Sigma Black Belt should be able to compute
univariate statistics for samples.
56. The Six Sigma Black Belt should be able to compute
confidence intervals for various statistics.
57. The Six Sigma Black Belt should be able to read
values from a cumulative frequency ogive.
58. The Six Sigma Black Belt should be familiar with the
commonly used probability distributions, including: hyper geometric, binomial,
Poisson, normal, exponential, chi-square, Student's t, and F.
59. Given a set of data the Six Sigma Black Belt should
be able to correctly identify which distribution should be used to perform a
given analysis, and to use the distribution to perform the analysis.
60. The Six Sigma Black Belt should know that different
techniques are required for analysis depending on whether a given measure
(e.g., the mean) is assumed known or estimated from a sample. The Six Sigma Black
Belt should choose and properly use the correct technique when provided with
data and sufficient information about the data.
61. Given a set of sub grouped data, the Six Sigma Black
Belt should be able to select and prepare the correct control charts and to
determine if a given process is in a state of statistical control.
62. The above should be demonstrated for data
representing all of the most common control charts.
63. The Six Sigma Black Belt should understand the
assumptions that underlie ANOVA, and be able to select and apply a
transformation to the data.
64. The Six Sigma Black Belt should be able to identify
which cause on a list of possible causes will most likely explain a non-random
pattern in the regression residuals.
65. If shown control chart patterns, the Six Sigma Black
Belt should be able to match the control chart with the correct situation
(e.g., an outlier pattern vs. a gradual trend matched to a tool breaking vs. a
machine gradually warming up).
66. The Six Sigma Black Belt should understand the
mechanics of PREControl.
67. The Six Sigma Black Belt should be able to correctly
apply EWMA charts to a process with serial correlation in the data.
68. Given a stable set of sub grouped data, the Six Sigma
Black Belt should be able to perform a complete Process Capability Analysis.
This includes computing and interpreting capability indices, estimating the % failures,
control limit calculations, etc.
69. The Six Sigma Black Belt should demonstrate an
awareness of the assumptions that underlie the use of capability indices.
70. Given the results of a replicated 22 full-factorial
experiment, the Six Sigma Black Belt should be able to complete the entire
ANOVA table.
71. The Six Sigma Black Belt should understand the basic
principles of planning a statistically designed experiment. This can be
demonstrated by critiquing various experimental plans with or without
shortcomings.
72. Given a "clean" experimental plan, the Six
Sigma Black Belt should be able to find the correct number of replicates to
obtain a desired power.
73. The Six Sigma Black Belt should know the difference
between the various types of experimental models (fixed-effects,
random-effects, mixed).
74. The Six Sigma Black Belt should understand the
concepts of randomization and blocking.
75. Given a set of data, the Six Sigma Black Belt should
be able to perform a Latin Square analysis and interpret the results.
76. Ditto for one way ANOVA, two way ANOVA (with and
without replicates), full and fractional factorials, and response surface
designs.
77. Given an appropriate experimental result, the Six
Sigma Black Belt should be able to compute the direction of steepest ascent.
78. Given a set of variables each at two levels, the Six
Sigma Black Belt can determine the correct experimental layout for a screening experiment
using a saturated design.
79. Given data for such an experiment, the Six Sigma
Black Belt can identify which main effects are significant and state the effect
of these factors.
80. Given two or more sets of responses to
categorical items (e.g.,customer survey responses categorized as poor, fair,
good, excellent),the Six Sigma Black Belt will be able to perform a Chi-Square
test to determine if the samples are significantly different.
81. The Six Sigma Black Belt will understand the idea of
confounding and be able to identify which two factor interactions are
confounded with the significant main effects.
82. The Six Sigma Black Belt will be able to state the
direction of steepest ascent from experimental data.
83. The Six Sigma Black Belt will understand fold over
designs and be able to identify the fold over design that will clear a given
alias.
84. The Six Sigma Black Belt will know how to augment a
factorial design to create a composite or central composite design.
85. The Six Sigma Black Belt will be able to evaluate the
diagnostics for an experiment.
86. The Six Sigma Black Belt will be able to identify the
need for a transformation in y and to apply the correct transformation.
87. Given a response surface equation in quadratic form,
the Six Sigma Black Belt will be able to compute the stationary point.
88. Given data (not graphics), the Six Sigma Black Belt
will be able to determine if the stationary point is a maximum, minimum or
saddle point.
89. The Six Sigma Black Belt will be able to use a
quadratic loss function to compute the cost of a given process.
90. The Six Sigma Black Belt will be able to conduct
simple and multiple linear regression.
91. The Six Sigma Black Belt will be able to identify
patterns in residuals from an improper regression model and to apply the
correct remedy.
92. The Six Sigma Black Belt will understand the
difference between regression and correlation studies.
93. The Six Sigma Black Belt will be able to perform
chi-square analysis of contingency tables.
94. The Six Sigma Black Belt will be able to compute
basic reliability statistics (mtbf, availability, etc.).
95. Given the failure rates for given subsystems, the Six
Sigma Black Belt will be able to use reliability apportionment to set mtbf
goals.
96. The Six Sigma Black Belt will be able to compute the
reliability of series, parallel, and series-parallel system configurations.
97. The Six Sigma Black Belt will demonstrate the ability
to create and read an FMEA analysis.
98. The Six Sigma Black Belt will demonstrate the ability
to create and read a fault tree.
99. Given distributions of strength and stress, the Six
Sigma Black Belt will be able to compute the probability of failure.
100. The Six Sigma Black Belt will be able to apply statistical
tolerance to set tolerances for simple assemblies. He will know how to compare statistical
tolerances to so-called "worst case" tolerance.
101. The Six Sigma Black Belt will be aware of the limits
of the Six Sigma approach.
8 comments:
Fantastic post and I must appreciate your work. Industry requires Six sigma black belt professionals for full-time, who act as a team leader for Six Sigma Project. Taking leadership role is not an easy task and it requires fulfilment of responsibilities and duties.
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Thank you so much Nancy!
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